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M65x
Measurement Centre and Transducer
User Manual
M65x
Measurement Centre and Transducer
Publication Reference:
M65x/EN/M/B © 2014. ALSTOM, the ALSTOM logo and any alternative version thereof are trademarks and service marks of ALSTOM. The other names mentioned,
registered or not, are the property of their respective companies. The technical and other data contained in this document is provided for information only. Neither
ALSTOM, its officers or employees accept responsibility for, or should be taken as making any representation or warranty (whether express or implied), as to the
accuracy or completeness of such data or the achievement of any projected performance criteria where these are indicated. ALSTOM reserves the right to revise or
change this data at any time without further notice.
M65x/EN/M/B
GRID
User Manual
M650, M651, M653
M65x/EN M/B
Page 1
CONTENTS
CERTIFICATION .............................................................................................................. 4
INSTALLATION AND MAINTENANCE ........................................................................... 4
COPYRIGHT NOTICE
5
TRADEMARKS................................................................................................................. 5
SAFETY SECTION
6
Health and safety ............................................................................................................ 6
Explanation of symbols and labels ............................................................................... 6
WARNING: EMISSIONS – CLASS A DEVICE (EN55011)............................................. 7
Decommissioning and Disposal.................................................................................... 8
1.0 DESCRIPTION & SPECIFICATIONS
9
1.1 Introduction .............................................................................................................. 9
1.2 Features .................................................................................................................... 9
1.3 Specifications............................................................................................................ 9
1.4 Standards and Certifications ................................................................................ 15
1.4.1 Revenue ........................................................................................................................... 15
1.5 Environment ........................................................................................................... 15
2.0 PHYSICAL CONSTRUCTION & MOUNTING
18
2.1 Installation .............................................................................................................. 22
2.2 Initial Inspection..................................................................................................... 22
2.3 Protective Ground/Earth Connections................................................................. 22
2.4 Overcurrent Protection.......................................................................................... 22
2.5 Supply/Mains Disconnect...................................................................................... 22
2.6 Instrument Mounting ............................................................................................. 22
2.7 Cleaning .................................................................................................................. 23
3.0 REAR PANEL & WIRING
24
3.1 Auxiliary Power ...................................................................................................... 25
3.1.1 Specifications (per section 1.3) ........................................................................................ 25
User Manual
M650, M651, M653
M65x/EN M/B
Page 2
3.2 VT Inputs – VA, VB, VC, VN (See Appendix A1 and Section 1.3)....................... 26
3.3 CT Inputs - IA, IB, IC (See Appendix A1 and section 1.3)................................... 26
3.4 Serial Port (See section 4.2).................................................................................. 27
3.5 Ethernet .................................................................................................................. 27
3.5.1 Network settings .............................................................................................................. 27
3.5.2 Indicators – Ethernet (ACT) & Serial LEDs ..................................................................... 29
3.5.3 Firmware upgrades – Ethernet service port .................................................................... 29
4.0 OPERATION
31
4.1 Display (not applicable to M651) .......................................................................... 31
4.1.1 Overview – Buttons Functions .......................................................................................... 39
4.1.2 Keypad Functions for Display Mode................................................................................. 40
4.1.3 Display Error Messages.................................................................................................... 41
4.2 Serial Port ............................................................................................................... 42
4.2.1 RS485 Connections......................................................................................................... 42
5.0 FUNCTIONAL DESCRIPTION
44
5.1 Configuration .......................................................................................................... 44
5.2 HTML Web Server .................................................................................................. 44
5.3 Passwords ............................................................................................................... 44
5.4 Navigating the M65x’s setup menu from the front panel ................................... 45
5.5 Performing set-up through the web page interface............................................ 51
6.0 MEASUREMENTS
64
6.1 Changing Transformer Ratios .............................................................................. 64
6.2 Current .................................................................................................................... 64
6.2.1 Residual Current.............................................................................................................. 64
6.3 Voltage Channels................................................................................................... 64
6.4 Voltage Aux ............................................................................................................ 65
6.5 Power Factor .......................................................................................................... 65
6.6 Watts / Volt-Amperes (VAs) / VARs...................................................................... 65
6.6.1 Geometric VA Calculations.............................................................................................. 65
6.7 Compensated Watts and VARs (Line and Transformer Loss Compensation). 67
6.8 Energy...................................................................................................................... 68
6.9 Frequency............................................................................................................... 68
User Manual
M650, M651, M653
6.10
M65x/EN M/B
Page 3
Demand Measurements .................................................................................... 68
6.10.1
6.10.2
6.10.3
6.10.4
6.10.5
Ampere and Fundamental Ampere Demand ................................................................. 69
Volt Demand................................................................................................................... 69
Power Demands (Total Watts, VARs, and VAs) ............................................................ 70
Demand Resets ............................................................................................................. 70
Demand Interval ............................................................................................................. 70
6.11 Harmonic Measurements .................................................................................... 70
6.11.1
6.11.2
6.11.3
6.11.4
6.11.5
6.11.6
6.11.7
Voltage Distortion (THD) ................................................................................................ 70
Current Distortion (THD and TDD)................................................................................. 70
Fundamental Current ..................................................................................................... 71
Fundamental Voltage ..................................................................................................... 71
K-Factor.......................................................................................................................... 72
Displacement Power Factor ........................................................................................... 72
Phase Angles ................................................................................................................. 72
6.12 Heartbeat and Health Check ............................................................................... 72
6.13 List of Available Measurements & Settings....................................................... 73
6.14 Calibration ............................................................................................................ 74
6.15 Instantaneous Measurement Principles ............................................................ 74
6.15.1 Sampling Rate and System Frequency ......................................................................... 74
7.0 ANALOGUE OUTPUT OPTION
75
7.1 Introduction ............................................................................................................ 75
7.2 Specifications......................................................................................................... 75
7.3 Connections ........................................................................................................... 75
8.0 SPLIT-CORE CT INPUT OPTION
78
8.1 Introduction ............................................................................................................. 78
8.2 Mounting .................................................................................................................. 78
8.3 Rear Panel and Wiring ............................................................................................ 79
APPENDIX
81
A1 CT/VT Connection Diagrams ................................................................................. 81
A2 Ethernet Troubleshooting...................................................................................... 85
A3 Display Screens – Visual Representations .......................................................... 86
User Manual
M65x/EN M/B
M650, M651, M653
Page 4
CERTIFICATION
Alstom Grid certifies that the calibration of our products is based on measurements using
equipment whose calibration is traceable to the United States National Institute of Standards
Technology (NIST).
INSTALLATION AND MAINTENANCE
Alstom Grid products are designed for ease of installation and maintenance. As with any
product of this nature, installation and maintenance can present electrical hazards and should
be performed only by properly trained and qualified personnel. If the equipment is used in a
manner not specified by Alstom Grid, the protection provided by the equipment may be
impaired.
In order to maintain UL recognition, the following Conditions of Acceptability shall apply:
a) After installation, all hazardous live parts shall be protected from contact by personnel or
enclosed in a suitable enclosure.
ASSISTANCE
For assistance, contact Alstom Grid Worldwide Contact Centre:
http://www.alstom.com/grid/contactcentre/
Tel: +44 (0) 1785 250 070
M65x Manual Set
M65x
User Manual
M65x
Modbus Protocol Manual
M65x
DNP3 Protocol Manual
User Manual
M65x/EN M/B
M650, M651, M653
Page 5
COPYRIGHT NOTICE
This manual is copyrighted and all rights are reserved. The distribution and sale of this manual
is intended for the use of the original purchaser or his agents. This document may not, in whole
or part, be copied, photocopied, reproduced, translated or reduced to any electronic medium or
machine-readable form without prior consent of Alstom Grid, except for use by the original
purchaser.
This manual incorporates information protected by copyright and owned by
Bitronics LLC, 261 Brodhead Road, Bethlehem, PA 18017.
Copyright © 2012 Bitronics, LLC. All rights reserved.
The product described by this manual contains hardware and software that is protected by
copyrights owned by one or more of the following entities:
Bitronics, LLC, 261 Brodhead Road, Bethlehem, PA 18017
Schneider Automation, Inc., One High Street, North Andover, MA 01845
Triangle MicroWorks, Inc., 2213 Middlefield Court, Raleigh, NC 27615
Freescale Semiconductor, Inc., 6501 William Cannon Drive West, Austin, TX 78735
gzip inflation uses code Copyright 2002-2008 Mark Adler
inarp uses WinPcap, which is Copyright 1999-2005 NetGroup, Politecnico di Torino (Italy), and
2005-2010 CACE Technologies, Davis (California).
TRADEMARKS
The following are trademarks or registered trademarks of Alstom Grid:
Alstom Grid
the Alstom Grid logo
The following are trademarks or registered trademarks of Bitronics LLC:
The Bitronics logo
Bitronics
The following are trademarks or registered trademarks of the DNP User's Group:
DNP
DNP3
The following are trademarks or registered trademarks of Schneider Automation, Inc.:
MODSOFT
Modicon
Modbus Plus
Modbus Compact 984 PLC
User Manual
M65x/EN M/B
M650, M651, M653
Page 6
SAFETY SECTION
This Safety Section should be read before commencing any work on the equipment.
Health and safety
The information in the Safety Section of the product documentation is intended to ensure that
products are properly installed and handled in order to maintain them in a safe condition. It is
assumed that everyone who will be associated with the equipment will be familiar with the
contents of the Safety Section.
Explanation of symbols and labels
The meaning of symbols and labels that may be used on the equipment or in the product
documentation is given below.
Installing, Commissioning and Servicing
Equipment connections
Personnel undertaking installation, commissioning or servicing work on this equipment should
be aware of the correct working procedures to ensure safety. The product documentation
should be consulted before installing, commissioning or servicing the equipment.
Terminals exposed during installation, commissioning and maintenance may present a
hazardous voltage unless the equipment is electrically isolated.
If there is unlocked access to the equipment, care should be taken by all personnel to avoid
electric shock or energy hazards.
Voltage and current connections should be made using insulated crimp terminations to ensure
that terminal block insulation requirements are maintained for safety. To ensure that wires are
correctly terminated, the correct crimp terminal and tool for the wire size should be used.
Before energizing the equipment, it must be grounded (earthed) using the protective ground
(earth) terminal, or the appropriate termination of the supply plug in the case of plug connected
equipment. Omitting or disconnecting the equipment ground (earth) may cause a safety hazard.
User Manual
M65x/EN M/B
M650, M651, M653
Page 7
2
The recommended minimum ground (earth) wire size is 2.5 mm (#12 AWG), unless otherwise
stated in the technical data section of the product documentation.
Before energizing the equipment, the following should be checked:
Voltage rating and polarity
CT circuit rating and integrity of connections
Protective fuse rating
Integrity of ground (earth) connection (where applicable)
Equipment operating conditions
The equipment should be operated within the specified electrical and environmental limits.
Current transformer circuits
Do not open the secondary circuit of a live CT since the high voltage produced may be lethal to
personnel and could damage insulation.
Insulation and dielectric strength testing
Insulation testing may leave capacitors charged up to a hazardous voltage. At the end of each
part of the test, the voltage should be gradually reduced to zero, to discharge capacitors, before
the test leads are disconnected.
Do not attempt to perform installation, maintenance, service or removal of this device without
taking the necessary safety precautions to avoid shock hazards. De-energize all live circuit
connections before work begins.
Fibre optic communication
Where fibre optic communication devices are fitted, these should not be viewed directly. Optical
power meters should be used to determine the operation or signal level of the device.
WARNING: EMISSIONS – CLASS A DEVICE (EN55011)
This is a Class A industrial device. Operation of this device in a residential area may cause
harmful interference, which may require the user to take adequate measures.
User Manual
M650, M651, M653
M65x/EN M/B
Page 8
Decommissioning and Disposal
1.
Decommissioning
The auxiliary supply circuit in the equipment may include capacitors across the supply or to
ground (earth). To avoid electric shock or energy hazards, after completely isolating the
supplies to the meter (both poles of any dc supply), the capacitors should be safely discharged
via the external terminals before decommissioning.
2.
Disposal
It is recommended that incineration and disposal to watercourses is avoided. The product
should be disposed of in a safe manner. Any products containing batteries should have them
removed before disposal, taking precautions to avoid short circuits. Particular regulations within
the country of operation may apply to the disposal of lithium batteries.
User Manual
M65x/EN M/B
M650, M651, M653
Page 9
1.0 DESCRIPTION & SPECIFICATIONS
1.1 Introduction
The M65x family of multifunction, Measurement centres and transducers provides a range of
measurement and communications capabilities for 3-phase metering. They offer an outstanding
display, superior communications flexibility and easy setup.
The M65x family consists of the following, which are covered by this manual
M650
M651
M653
Measurement Centre
Multifunction Transducer
Measurement Centre with 3 simultaneous displays
Any mention of Displays and Keypad buttons in this manual does not apply to the M651
Transducer.
1.2 Features
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
Full basic measurement set with optional demand and harmonic values
0.2% revenue accuracy
Updates every 100ms
DNP3 or Modbus protocol available via configurable RS-232/RS-485 serial port
Available Ethernet protocol support for DNP3 TCP/UDP or Modbus TCP
Web Based configuration via Ethernet service port
Wide-range universal power supply
Rugged aluminium case
One model covers all wiring options
Standard 4” round meter or transducer, M653 can be mounted in a 19” 3U panel
3-line at once, easy-to-read, long-life LED displays (not M651)
Ultimate precision with five digits per line (not M651)
Instant recognition of the displayed function from the alphanumeric display in
engineering units (not M651)
Easy setup and scrolling from front display with “Touch-Sense” buttons (not M651)
Optional Split Core CT inputs, whilst maintaining instrument accuracy
1.3 Specifications
Power Supply Input (Auxiliary) Voltage – terminals L1(+) and L2(-)
Installation Category (Auxiliary Power Supply) – CAT II
Nominal:
48-250V dc, 69-240V ac (50/60Hz)
Operating Range:
36-300V dc, 55-275V ac (45-65Hz)
Burden:
8W max, 24VA max
Display:
Three separate displays, each with 3 lines of 5 digits, red
LED, 15mm (0.56”) high, and 1 line of 8 characters
alphanumeric, red LED, 5mm (0.20”) high. ( x3 on M653)
Display Interface:
4 buttons on centre display plus right and left buttons on
M653
User Manual
M65x/EN M/B
M650, M651, M653
Page 10
Input Signals – Measurement Inputs
CT
Current
Inputs
Configuration
All Input Options
3 Inputs. 3 Phase Currents (IA, IB, IC).
Nominal
Input Option 1
1A ac
Input Option 5
5A ac
Input Option C
5A ac with split-core CTs
Input Option 1
0 to 2A rms continuous at all rated temperatures
Input Option 5
0 to 10A rms continuous at all rated temperatures
Input Option C
0 to 10A rms continuous at all rated temperatures
Input Option 1
Withstands 30A ac continuous, 400Aac for 2 seconds
Input Option 5
Withstands 30A ac continuous, 400Aac for 2 seconds
Input Option C
Not applicable
Input Option 1
2500V ac, minimum.
Input Option 5
2500V ac, minimum.
Input Option C
2500V ac, minimum, with external split core transducers
Input Option 1
0.016VA @ 1A rms, 60Hz (0.0016ohms @ 60Hz)
Input Option 5
0.04VA @ 5A rms, 60Hz (0.0016ohms @ 60Hz)
Input Option C
Not applicable
All Input Options
45-65 Hz
Range
Overload
Isolation
Burden
Frequency
VT (PT)
Voltage
Inputs
Configuration
Nominal
4 Inputs, Measures 1 Bus, 3 or 4 Wire. 3 Phase Voltages (VA, VB, VC, VN). See
Appendix A1 Connection Diagrams.
120Vac
Range
0 to 150V rms
System Voltage
Intended for use on nominal system voltages up to 208 V rms, phase-to-phase
(120V rms, phase-to-neutral).
Reads to 400V peak, any input-to-case (ground)
Common Mode Input
Voltage
User Manual
M65x/EN M/B
M650, M651, M653
Page 11
Input Signals – Measurement Inputs
Impedance
>12M ohms, input-to-case (ground)
Voltage Withstand
2.5kV rms 1min, input-to-case (ground)
2kV rms 1min, input-to-input
45-65 Hz
Frequency
Sampling System
Sample Rate
64 samples per cycle
Data Update Rate
Amps, Volts
Available every 100 ms
Watts, VAs, VARs, PF
Available every 100 ms
Number of Bits
16
User Manual
M65x/EN M/B
M650, M651, M653
Page 12
Communication Ports
Serial (option*)
RS-232, RS-485, Software configurable ports
Baud rate: 9600 bps to 115.2 kbps
Ethernet
Single port; copper 10/100 Base-TX (standard)
Single port; LC fibre 100 Base-FX (option)
Analogue Transducer Outputs (option*)
Refer to section 7.0 for specifications
*Either the serial port or analogue output may be ordered as an option, but not both
Accuracy
Accuracies are specified at nominal Frequency and 25C, (unless otherwise noted). Unless noted, all values are true RMS and include Harmonics
to the 31st (minimum).
Voltage
AC: Better than 0.1% of reading (20 to 150 V rms, input-to-case). (+/- 25ppm/DegC)
Voltage Aux
Current
Only included with meters
manufactured with the
monitoring option
Input option 1 (Internal
Isolation - 1A ac)
AC/DC: Better than 1.0% of reading
Better than 0.1% of reading +/- 20uA (>0.1A to 2.0A, -20C to 70C)
Better than 0.1% of reading +/- 50uA (0.01A to 0.1A, -20C to 70C)
Minimum reading 1mA
Input option 5 (Internal
Isolation - 5A ac)
Better than 0.1% of reading +/- 100uA (>0.5A to 10.0A, -20C to 70C)
Better than 0.1% of reading +/- 250uA (0.05A to 0.5A, -20C to 70C)
Minimum reading 5mA
Input option C (External
Split-Core CTs)
Better than 0.1% of reading +/- 100uA (>0.5A to 10.0A, -20C to 70C)
Better than 0.1% of reading +/- 250uA (0.05A to 0.5A, -20C to 70C)
Minimum reading 5mA
Frequency
+/- 0.001 Hertz
+/- 0.001 Hertz
Power
Meets or exceeds IEC
60687 0.2S
Meets or exceeds IEC 60687 0.2S
User Manual
M65x/EN M/B
M650, M651, M653
Page 13
Environmental
Operating Temperature
-40°C to +70°C
Relative Humidity
0-95% non-condensing
Measurement Inputs (VTs,
CTs)
Installation/Measurement
Category
Pollution Degree
CAT III (Distribution Level): Refer to definitions below.
Enclosure Protection
(to IEC60529: 2001)
Altitude
Intended Use
Pollution Degree 2: Refer to definitions below.
Front Panel: IP 20, Rear: IP 20
When equipment is mounted in an appropriately rated protective enclosure to NEMA or IP protection classifications,
as required for the installation. Ratings are applicable for enclosure category 2 (see definitions)
Up to and including 2000m above sea level
Indoor use; Indoor/Outdoor use when mounted in an appropriately rated protective enclosure to NEMA or IP
protection classifications, as required for the installation.
Class 1 equipment to IEC61140: 2001
User Manual
M65x/EN M/B
M650, M651, M653
Page 14
Physical
Connections
Protective
Conductor
Terminal
Current
(CT)
Voltage
(VT) &
(AUX
PWR)
Serial Port
Ethernet
(optional)
Ethernet
Weight
(typical)
Size
10-32 Studs for connection with protective earth ground. Recommended Torque: 1.36 N-m (12 in-lbs).
Cable temperature rating: 85C minimum
Internal Isolation - Current Input Option 1 or 5. 10-32 Studs for current inputs. Recommended Torque: 1.36 N-m
(12 in-lbs). Cable temperature rating: 85C minimum
2
External Split-Core CTs – Current Input Option C: Terminal Block accepts #22-12 AWG (0.35 to 3.3mm ) wire, or
terminal lugs up to 0.325" (8.26mm) wide.
Recommended Torque: 1.02 N-m (9 in-lbs).
Cable temperature rating: 85C minimum
2
Terminal Block accepts #22-10 AWG (0.35 to 5mm ) wire, or terminal lugs up to 9.53mm (0.375”) wide.
Precautions must be taken to prevent shorting of lugs at the terminal block.
A minimum distance of 3mm (1/8”) is recommended between uninsulated lugs to maintain insulation requirements.
Recommended Torque: 1.02 N-m (9 in-lbs)
Cable temperature rating: 85C minimum
6 position removable terminal block, accepts 26-14AWG solid or 26-12 AWG stranded wire. Recommended
Torque 0.79 N-m (7 in-lbs).
Cable temperature rating: 85C minimum
LC connector fibre port
RJ45, 8 position modular jack, Category 5 for copper connection; 100m (328 ft.) UTP (unshielded twisted pair)
cable.
0.82Kg (1.8 lbs) or 1.5 Kg (3.4 lbs).
Industry standard 4” round case, 178mm (7.0 in) long
User Manual
M65x/EN M/B
M650, M651, M653
Page 15
Definitions:
Enclosure Category 2: Enclosures where no pressure difference relative to the surrounding air
is present.
Installation Category II (Overvoltage Category II) or CAT II: Equipment is intended for
connection to the fixed installation of a building. The power supply to the electronic equipment
is separated from other circuits, usually by a dedicated transformer for the mains power supply.
Measurement/Installation Category III (Overvoltage Category III) or CAT III: Distribution
Level, fixed installation, with smaller transient overvoltages than those at the primary supply
level, overhead lines, cable systems, etc.
Pollution: Any degree of foreign matter, solid, liquid, or gaseous that can result in a reduction
of electric strength or surface resistivity of the insulation.
Pollution Degree 2: Only non-conductive pollution occurs except that occasionally a temporary
conductivity caused by condensation is to be expected.
1.4 Standards and Certifications
1.4.1 Revenue
The M65x family of meters exceeds the accuracy requirements of ANSI C12.20 and IEC 60687
(or IEC62053-22).
Type
M3
Nominal Current
1A, 5A
Certification
ANSI C12.20, 0.2CA
IEC 60687 (or 62053-22), 0,2S
The M65x meters were tested for compliance with the accuracy portions of the standards only.
The form factor of the M65x meters differs from the physical construction of revenue meters
specified by the ANSI/IEC standards and no attempt has been made to comply with the
standards in whole.
1.5 Environment
UL/CSA Recognized, File Number E164178
UL61010-1, Edition 3, Issue Date 2012/05/11
Safety Requirements for Electrical Equipment for Measurement, Control, and Laboratory Use –
Part 1: General Requirements
UL61010-2-30, Edition 1 – Issue Date 2012/05/11
Safety Requirements for Electrical Equipment for Measurement, Control, and Laboratory Use –
Part 2: Particular Requirements for Testing and Measuring Circuits
CSA C22.2 No. 61010-1-12-CAN/CSA, Edition 3, Issue Date 2012/05/01
CAN/CSA Safety Requirements for Electrical Equipment for Measurement, Control, and
Laboratory Use – Part 1: General Requirements
CSA C22.2 No. 61010-2-30-12-CAN/CSA, Edition 1 – Issue Date 2012/05/01
Safety Requirements for Electrical Equipment for Measurement, Control, and Laboratory Use –
Part 2-030: Particular Requirements for Testing and Measuring Circuits
User Manual
M65x/EN M/B
M650, M651, M653
Page 16
If applicable, the CE mark must be prominently marked on the case label.
European Community Directive on EMC 2004/108/EC and Directive 91/263/EC
[TTE/SES].
European Community Directive on Low Voltage 2006/95/EC)
Product and Generic Standards
The following product and generic standards were used to establish conformity:
Low Voltage (Product Safety)
IEC 61010-1, Edition 3, Issue Date 2013/02/01
Safety Requirements for Electrical Equipment for Measurement, Control, and Laboratory Use –
Part 1: General Requirements
IEC 61010-2-30, Edition 1 – Issue Date 2010/06/02
Safety Requirements for Electrical Equipment for Measurement, Control, and Laboratory Use –
Part 2-030: Particular Requirements for Testing and Measuring Circuits
EMC: EN 61326-1: 2013 (Supersedes EN61326-1: 2006), EN 61000-6-2: 2005,
EN 61000-6-4: 2007/ A1:2011 (IEC date 2010)
Radiated Emissions Electric Field Strength
EN 55011: 2009/ A1: 2010
EN 61000-6-4: 2007/ A1:2011 (IEC date 2010)
Group 1, Class A
Frequency: 30 - 1000 MHz
AC Powerline Conducted Emissions
EN 55011: 2009/ A1: 2010
EN 61000-6-4: 2007/ A1:2011 (IEC date 2010)
Group 1, Class A
Frequency: 150 kHz – 30 MHz
Electrostatic Discharge (ESD)
EN61000-4-2: 2009
Discharge voltage: ± 8 KV Air; ± 4 KV Contact & Additionally meets ± 6 KV Contact
Immunity to Radiated Electromagnetic Energy (Radio Frequency)
EN 61000-4-3: 2006/ A1: 2008/ A2:2010, Class III
Frequency: 80 – 1000 MHz, Modulation: 80% AM @ 1 kHz
Frequency: 1400 – 2000 MHz, Amplitude: 3.0 V/m, Modulation: 80% AM @ 1 kHz
Frequency: 2000 – 2700 MHz Amplitude: 1.0 V/m Modulation: 80% AM @ 1 kHz
Digital Radio Telephones:
Frequency: 900 MHz & 1890 MHz, Amplitude: 10.0 V/m, 3.0 V/m,
Modulation: 80% AM @1kHz
Electrical Fast Transient / Burst Immunity
EN 61000-4-4: 2012 (supersedes EN 61000-4-4: 2004/ A1:2010)
Burst Frequency: 5 kHz
Amplitude, AC Power Port: ± 4 KV (Severity Level 4), exceeds ± 2 KV requirement
Amplitude, Signal Port: ± 1 KV, Additionally meets ± 2 KV (Severity Level 3)
Amplitude, Telecom ports (Ethernet): ± 1 KV
Current/Voltage Surge Immunity
EN 61000-4-5: 2007 (supersedes EN 61000-4-5: 2006)
Open Circuit Voltage: 1.2 / 50 s
Short Circuit Current: 8 / 20 s
Amplitude, AC Power Port: 2 KV common mode, 1 KV differential mode
User Manual
M650, M651, M653
Immunity to Conducted Disturbances Induced by Radio Frequency Fields
EN 61000-4-6: 2009
Level: 3
Frequency: 150 kHz – 80 MHz
Amplitude: 10 V rms
Modulation: 80% AM @ 1 kHz
Power Frequency Magnetic Fields
EN 61000-4-8: 2010
Amplitude: 30A/m
Frequency: 50 and 60 Hz
AC Supply Voltage Dips and Short Interruptions
EN 61000-4-11: 2004
Surge Withstand Capability Test For Protective Relays and Relay Systems
ANSI/IEEE C37.90.1: 2002 (2.5 kV oscillatory wave and 4 kV EFT)
M65x/EN M/B
Page 17
User Manual
M65x/EN M/B
M650, M651, M653
Page 18
2.0 PHYSICAL CONSTRUCTION & MOUNTING
M650
The M650 meters are packaged in rugged aluminium case specifically designed to meet the
harsh conditions found in utility and industrial applications.
The Front panel view is shown in Figure 1a. The mechanical dimensions are shown in Figure
2a.
Figure 1a – M650 Front View
User Manual
M650, M651, M653
M65x/EN M/B
Page 19
M651
The M651 digital transducers are packaged in rugged aluminium case specifically designed to
meet the harsh conditions found in utility and industrial applications.
The mounting plate panel view is shown in Figure 1b. The mechanical dimensions are shown in
Figure 2b.
Figure 1b – M651 Mounting Plate View
M653
The M653 meters are packaged in a rugged aluminium case mounted on an aluminium 19” 3U
panel or as a 14" panel mount version and are specifically designed to meet the harsh
conditions found in utility and industrial applications.
The Front panel view is shown in Figure 1c. The mechanical dimensions are shown in Figure
2c.
Figure 1c – M653 Rack mount version Front View
User Manual
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Figure 2a - Mounting and Overall Dimensions M650
Figure 2b - Mounting and Overall Dimensions M651
M65x/EN M/B
Page 20
User Manual
M65x/EN M/B
M650, M651, M653
Figure 2c - Mounting and Overall Dimensions M653
(rack mount above, panel mount below; back panel may vary due to options ordered)
Page 21
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2.1 Installation
WARNING - INSTALLATION AND MAINTENANCE SHOULD ONLY BE PERFORMED BY
PROPERLY TRAINED OR QUALIFIED PERSONNEL.
2.2 Initial Inspection
Alstom Grid instruments are carefully checked and "burned in" at the factory before shipment.
Damage can occur however, so please check the instrument for shipping damage as it is
unpacked. Notify Alstom Grid immediately if any damage has occurred, and save any damaged
shipping containers.
2.3 Protective Ground/Earth Connections
The device must be connected to Protected Earth Ground. The minimum Protective Ground
2
wire size is 2.5 mm (#12 AWG). Alstom Grid recommends that all grounding be performed in
accordance with ANSI/IEEE C57.13.3-1983.
2.4 Overcurrent Protection
To maintain the safety features of this product, a 3 Ampere time delay (T) fuse must be
connected in series with the ungrounded/non-earthed (hot) side of the supply input prior to
installation. The fuse must carry a voltage rating appropriate for the power system on which it is
to be used. A 3 Ampere slow blow UL Listed fuse in an appropriate fuse holder should be used
in order to maintain any UL product approval.
2.5 Supply/Mains Disconnect
Equipment shall be provided with a Supply/Mains Disconnect that can be actuated by the
operator and simultaneously open both sides of the mains input line. The Disconnect should be
UL Recognized in order to maintain any UL product approval. The Disconnect should be
acceptable for the application and adequately rated for the equipment.
2.6 Instrument Mounting
M650
The M650 may be mounted into a standard 4” round panel opening as shown in Figure 2a. The
unit will mount through the 4-inch round panel opening from the front. Align the four #10-32
studs attached to the flange with their appropriate mounting holes, as shown by the panel hole
pattern. Use four #10-32 nuts with lock washers applied onto the studs from the back side of
the panel. Make sure that any paint or other coatings on the panel do not prevent
electrical contact.
WARNING – DO NOT over tighten the nuts on the mounting studs, HAND tighten with a
standard nut driver, 1.35 N-m (12 in-lbs) is recommended, MAXIMUM torque is 1.7 N-m (15 inlbs).
Several instruments may be mounted on a 19" Rack panel if desired. Three units will fit side by
side on a standard (3U) 133mm (5.25") high panel. Figure 2a indicates the dimensions of the
panel hole cut-out. Leave adequate space surrounding the instrument when determining
mounting arrangements.
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M65x/EN M/B
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M651
The M651 transducer may be surface mounted as shown in Figure 2b. The instrument may be
mounted on a standard transducer mounting hole pattern. The unit should be mounted with
four #8-32 screws. The transducer is intended to be connected to earth ground at the mounting
plate. Make sure that any paint or other coatings on the panel do not prevent electrical
contact.
Several instruments may be mounted on a 19" Rack panel if desired. Three units will fit side by
side on a standard 133mm (5.25") high panel. Leave adequate space surrounding the
instrument when determining mounting arrangements
M653
The rack mount version may be mounted into a standard 19”, 3U high rack opening. The panel
mount version may be mounted into a standard 4” round panel opening as shown in Figure 2c.
The unit will mount through the 4-inch round panel opening from the front. Align the four #10-32
studs attached to the flange with their appropriate mounting holes, as shown by the panel hole
pattern. Use four #10-32 nuts with lock washers applied onto the studs from the back side of
the panel. Make sure that any paint or other coatings on the panel do not prevent
electrical contact.
WARNING – If the meter is removed from the panel at any time upon reinstalling, DO NOT over
tighten the nuts on the mounting studs, HAND tighten with a standard nut driver, 1.36 N-m (12
in-lbs) is recommended, MAXIMUM torque is 1.69 N-m (15 in-lbs).
Split Core CT
For details of mounting the optional split-core CTs - – Refer to section 8
2.7 Cleaning
Cleaning the exterior of the instrument shall be limited to the wiping of the instrument using a
soft damp cloth applicator with cleaning agents that are not alcohol based, and are nonflammable and non-explosive.
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M65x/EN M/B
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3.0 REAR PANEL & WIRING
The rear views of the M65x are shown in figures 3a and 3b with the option port shown
(removable terminal block at the top), which may be selected at order time, as either, the serial
communication option, the 0-1mA analogue output option, or the 4-20mA analogue output
option. However, it is also possible to have a meter without this option port.
See Appendix A1 for detailed wiring diagrams covering the CT/VT measurement inputs. Refer
to the appropriate section in this user manual when wiring either the serial communication
option, or either analogue output option, whichever applies to the option port for your meter.
Figure 3a – Rear View M65x (shown with Current (CT) Inputs with internal isolation (#1032 stud terminals) – Current Input Option 1 or 5)
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Figure 3b –Rear View M65x (shown with 6 position terminal block for External Split-Core
CTs – Current Input Option C)
3.1 Auxiliary Power
The M65x meters are powered by connections to L1(+) and L2(-). A Blue LED Power (PWR)
indicator is provided on the rear panel to indicate that the unit is powered ON. It is located on
the right of the rear panel.
There is an option that allows the voltage across the Auxiliary Power input voltage across
terminals L1(+) and L2(-) to be monitored. This monitoring option is only found in M65x that
have been manufactured with this monitoring option. Refer to the order guide to verify whether
the meter is made with this monitoring option. ‘V Aux’ will appear on the display as a
measurement on meters equipped with this monitoring option and the measured values can be
obtained via the communications.
3.1.1 Specifications (per section 1.3)
Power Supply Input (Auxiliary) Voltage – terminals L1(+) and L2(-)
Nominal:
48-250V dc, 69-240V ac (50/60Hz)
Operating Range:
36-300V dc, 55-275V ac (45-65Hz)
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3.2 VT Inputs – VA, VB, VC, VN (See Appendix A1 and Section 1.3)
The M65x voltage (VT) signal inputs are connected to terminals 3-6 (see Appendix A1 for
specific wiring configurations). Voltage signals are measured using a 12M ohm resistor divider
with a continuous voltage rating of 7kV. This ideal impedance provides a low burden load for
the VT circuits supplying the signals. Grounding of VT & CT signals per ANSI/IEEE C57.13.31983 is recommended. The polarity of the applied signals is important to the function of the
instrument.
3.3 CT Inputs - IA, IB, IC (See Appendix A1 and section 1.3)
The M65x can be connected directly to a current transformer (CT). The Current (CT) signal
inputs are connected to terminals 7-12.
Several hardware options are offered for the M65x current inputs. Distinctions are based on the
current option ordered and the physical constructions.
The 1 Amp and 5 Amp current inputs, current input options 1 and 5 respectively, feature 10-32
terminals to assure reliable connections. This results in a robust current input (CT) connection
with negligible burden to ensure that the user’s external CT circuit can’t ever open-circuit, even
under extreme fault conditions. Grounding of CT signals per ANSI/IEEE C57.13.3-1983 is
required.
Current inputs, option 1: 1 Amp input with internal current isolation transformer, constructed
with 10-32 studs as the current terminals. (See Figure 3a for the physical construction
shown for the current terminals). It is intended that this meter connects to the output from the
secondary of permanently installed Current Transformers (CTs).
WARNING: DO NOT loosen existing 10-32 hardware that secures the current input studs to the
back panel. When making connections to the current input studs, use #10 ring lugs. Fasten ring
lugs with the 10-32 bagged hardware (flat washer, lock washer, and nut) provided. DO NOT
OVERTORQUE. HAND Tighten with a standard nut driver. 1.36 N-m (12 in-lbs) is
recommended, MAXIMUM torque is 1.69 N-m (15 in-lbs).
Current inputs, option 5: 5 Amp input with internal current isolation transformer, constructed
with 10-32 studs as the current terminals. (See Figure 3a for the physical construction
shown for the current terminals). It is intended that this meter connects to the output from the
secondary of permanently installed Current Transformers (CTs).
WARNING: DO NOT loosen existing 10-32 hardware that secures the current input studs to the
back panel. When making connections to the current input studs, use #10 ring lugs. Fasten ring
lugs with the 10-32 bagged hardware (flat washer, lock washer, and nut) provided. DO NOT
OVERTORQUE. HAND Tighten with a standard nut driver. 1.36 N-m (12 in-lbs) is
recommended, MAXIMUM torque is 1.69 N-m (15 in-lbs).
Current inputs option C: This option is used with external Split core CTs. External split core
CT secondary wires connect to the current terminal block (see figure 3b). The Current inputs
for this model are touch safe. No internal current isolation is provided within the meter. DO
NOT CONNECT Hazardous Live voltages to the current input terminal block. Only connect the
external Split Core CT secondary current outputs to the meter’s current input terminal block.
Isolation is provided from the external Split Core CTs. Recommended torque is 1.02 N-m (9 inlbs).
For additional details of the optional split-core CTs refer to section 8.
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M650, M651, M653
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3.4 Serial Port (See section 4.2)
The M65x meters are equipped with an optional serial port. The port is software (user)
configurable for RS-232 or RS-485. The RS-232 drivers support full and half duplex modes.
See Figures 7-8 for signal assignments.
3.5 Ethernet
The M65x Ethernet port meets or exceeds all requirements of ANSI/IEEE Std 802.3 (IEC 88023:2000) and additionally meets the requirements of part 8-1 TCP/IP T-profile for physical layer 1
(Ethernet copper interface).
M65x meters are offered with a standard Ethernet 10/100 Megabit (Mb) RJ45 (copper) interface
(10BASE-T and 100BASE-TX) which automatically selects the most appropriate operating
conditions via auto-negotiation. This interface is capable of operating either as half-duplex
(compatible with all Ethernet infrastructures) or full-duplex interfaces (which allow a potential
doubling of network traffic). Note that the meters come with the port setup as a service port,
with Modbus TCP/IP or DNP3 TCP/IP or UDP software offered as an option. An option to
replace the standard RJ45 port with a LC 100BASE-FX fibre port also exists, operating at 1300
nm (far infra-red), full-duplex.
3.5.1 Network settings
The M65x meters come preconfigured for interconnection to an HTML web server with default
settings for IP address, SUBNET mask, and ROUTER (GATEWAY) address.
Network Default (Preconfigured) Settings
IP Address
Subnet mask
Router (Gateway) Address
192.168.0.171
192.168.0.1
255.255.255.0
It is very important that the network have no duplicate IP addresses, so that an IP address
conflict is NOT created for your network. It is recommended to perform your initial setup for
network addresses using the front buttons on the meter, unless it is known that the default
(preconfigured) IP address is not already an assigned address on your network. Changing the
stored Configuration of these network addresses may be accomplished by using one of the
following methods
Enter Network addresses using the meter’s front buttons (not M651):
Refer to the section in this manual on “Navigating the M65x’s setup menu from the Front panel”
for further instruction regarding the button sequence you will use to scroll through the menu
structure. This will provide a handy menu tree.
Activate the setup mode using the front buttons on the meter by pressing the Up + Toggle (Exit)
buttons simultaneously. Scroll to menu selection “1.3”, “Network”, in order to change the
Network settings. Enter an IP address that you know is an unassigned address for your
network. You can ping the IP address to make sure it is not already in use on your network.
You may also want to check with your network administrator to make sure the IP address you
plan on using is available to use on your network. After entering the Network addresses exit out
of the menu, and when prompted to save the new configuration settings, press the button
directly under the SAVE prompt identified as “Y” (Yes). Reboot the meter for the configuration
changes to take effect.
Enter the IP Address for the meter through a standard web browser:
Before entering an IP address with this method make sure the current IP address and the new
IP address to be assigned to the meter will not cause IP address conflicts on your local network.
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To connect to the web server enter the meter’s current IP Address in your web browser’s
address bar. When the web server screen appears click on the “Settings” tab. Type the new
Network settings (IP address, Subnet mask, Gateway) in the appropriate fields and click the
“Apply” button to send the new network settings to the meter. Reboot the meter for the
configuration change to take effect.
The M65x uses the following port numbers for each type of protocol:
Protocol
Port Number
DNP3
HTML
Modbus
20000 (TCP, UDP)
80 (TCP)
502 (TCP)
Determining the IP Address if unknown:
Although the IP address can be obtained via the display, for the M651 which does not have a
display, a utility program has been created to request the IP address for a specific MAC address
on an Ethernet network. This program can be used with the M650 and M653 as well. The
program is available on website (http://www.novatechweb.com/downloads/inarp/).). The
program uses the Inverse Address Recognition Protocol to perform the lookup and thus is called
inarp. The InARP protocol definition can be found at www.apps.ietf.org/rfc/rfc2390.html. The
inarp utility can also scan an Ethernet network for a range of MAC addresses, printing the IP
address for any devices which respond.
Currently, the only Alstom Grid devices which respond to inarp are M65x products with a
release code >= 2.00.0.
The general form of inarp is defined below, followed by some usage examples.
inarp usage:
inarp [-i <if_ipaddr>] [-n <cnt>] [-p <ms>] [-v] <mac-spec>
where
<if_ipaddr> := interface ip address (default is 1st Ethernet interface)
<cnt> := count of addresses to poll (default 1)
<ms> := period between polls (100ms)
<mac-spec> := <6ByteMac> | <[3-5]ByteMac> | <macRangeName>
<6ByteMac> := xx:xx:xx:xx:xx:xx - <cnt> can specify a range to scan
<5ByteMac> := xx:xx:xx:xx:xx - default <cnt> is 256
...
<3ByteMac> := xx:xx:xx - default <cnt> is 16,777,216
<macRangeName> := "50series"
50Series MAC base (00:d0:4F:03), default <cnt> is 65,536
-v := request verbose information
CTRL-C stops a scan.
The inarp utility requires the WinPcap and Packet libraries which are bundled in the
WinPcap "Installer for Windows." This can be downloaded from www.winpcap.org.
Installation requires Administrator privileges.
To use the inarp utility, open a ‘cmd’ window and change the directory to the location where
inarp.exe is stored. Then type the commands as defined below
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Examples:
to poll the 1st IPv4 interface,
inarp -v 50series
CTRL-C stops the scan
This scan takes some minutes to poll the full range of MAC addresses.
to poll the IPv4 interface associated with 192.168.1.1, use
inarp -v -i 192.168.1.1 50series
or to poll a specific MAC, use
inarp -v -i 192.168.1.1 00:D0:4F:03:00:15
The inarp utility is Copyright (c) 2011 by Bitronics, LLC. All rights reserved.
Portions of inarp are
Copyright (c) 1999 - 2005 NetGroup, Politecnico di Torino (Italy), and
Copyright (c) 2005 - 2010 CACE Technologies, Davis (California)
3.5.2 Indicators – Ethernet (ACT) & Serial LEDs
There are 2 LEDs on the rear panel to indicate activity is occurring on the communication ports.
These LEDs are useful in determining that there is activity occurring on the ports. The "ACT"
LED will flash to indicate there is activity on the Ethernet port. It will also indicate that a link has
been established. The Serial LED flashes to indicate there is activity occurring for the serial
port.
A troubleshooting guide is found in Appendix A2, which may be useful in establishing Ethernet
connections.
3.5.3 Firmware upgrades – Ethernet service port
New versions of firmware may be released by Alstom Grid from time to time, either to add new
functionality or to correct errors in code that may have escaped detection prior to commercial
release. Consult the factory for detailed information pertaining to the availability of firmware
upgrades. In cases such as this, it is desirable to support a mechanism for new firmware to be
installed remotely. The ability to upgrade the Firmware is done over the Ethernet port. The
M65x family utilizes a page in the Web Server interface to upload and install new firmware. A
password protected hyperlink is provided from the Configuration Settings Page that navigates to
the Firmware Upload page.
First obtain a copy of the firmware image. The firmware image is a binary file, less than 1 MB in
length, that can be attached to email, distributed on a CD, or downloaded from an FTP site as
circumstances dictate. Place a copy of the firmware image on your computer then access the
upload page from the Firmware Update link on the Configuration Settings page.
This will take you to the firmware upload page, which looks like the screen capture in Figure 4.
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M65x/EN M/B
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Figure 4 –M65x Firmware Upload Page
Once the Firmware Upload page is visible, use the Browse button to locate the firmware image
on your computer. Next use the Submit button to initiate the file transfer and installation
process. The instrument must be rebooted to make the new firmware active. At the completion
of the file transfer and installation process, the instrument will prompt you to reset the instrument
remotely by displaying the dialog box below after the firmware has been successfully installed.
It is strongly recommended that you clear your web browser’s cache (delete the temporary
internet files) after updating the firmware so that the new content will be loaded into your
browser. Please refer to your browser’s help file on how to clear the cache. A useful keyboard
shortcut common to Internet Explorer, Firefox and Chrome is CONTROL + SHIFT + DELETE,
which will take you directly to the relevant panel. Carefully select the items to be cleared. Be
sure to check the boxes that clear “temporary internet files”, “cache” or “website data” and
uncheck any boxes that preserve data.
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4.0 OPERATION
4.1 Display (not applicable to M651)
The M650 can display several per-phase and total quantities for the circuit being monitored. In
order to make all quantities available, the display scrolls from quantity to quantity approximately
every 5 seconds. The quantities are refreshed once a second. The Alphanumeric display at
the bottom of the instrument indicates to the user what quantity is being displayed. The
Alphanumeric display also provides the user with primary engineering units (Watts, kWatts,
MWatts, etc.).
The Middle Display of the M653 retains all the functionality of the M650 Display including
Scrolling, Home Screen designation, Custom screens, Setup mode, etc. The M653 adds a Left
Display, a Right Display, a Left Button and a Right Button to the front panel. All three displays
can display several per-phase and total quantities for the circuit being monitored.
Any pre-defined or custom screen that is displayed on the Middle Display of the M653 can be
copied to the Left or Right Display by pressing the corresponding Left or Right button on the
front panel. The last selection made is retained through power down events. In addition to the
front panel buttons, the screen selection for the Left and Right Display may be made on the
Settings/Screen Enable webpage. The screens that appear on the left and right displays do not
need to be enabled on the middle display.
Listed on the following pages are standard screens available in the M65x. Configurable screen
enable settings allow the user to enable or disable each of the display screens, in order to view
only a selected subset of all the measurements the meter is capable of displaying. Refer to the
section in this manual on Setup Mode for instructions on programming Screen Enable Settings
1.6
(Setup menu - Scrn Ena).
The following screens are enabled by default:
Amps A,B,C
Volts AN,BN,CN
Volts AB,BC,CA
Total Watts / Total Vars
VAs Total / Power Factor
Frequency
Demand Amps A,B,C
The Default HOME screen is:
Amps A,B,C.
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INSTANTANEOUS DISPLAY SCREENS
Format
Quantity
1.
00000
00000
00000
AmpsΦ
Phase A Amperes
Phase B Amperes
Phase C Amperes
2.
00000


AmpsR
Residual Amperes
Unused
Unused
3.
00000
00000
00000
xVolts
Phase A Volts
Phase B Volts
Phase C Volts
4
00000
00000
00000
xVolts
Phase A-B Volts
Phase B-C Volts
Phase C-A Volts
5.
00000
00000
00000
xWatts Φ
Phase A Watts
Phase B Watts
Phase C Watts
1
6.
00000
00000
00000
xVAR Φ
Phase A VARs
Phase B VARs
Phase C VARs
1
7.
00000
00000

xWxVAR
Total Watts
Total VARs
Unused
8.
00000
00000
00000
xVA Φ
Phase A VAs
Phase B VAs
Phase C VAs
9.
00000
00000
00000
PF Φ
Phase A PF
Phase B PF
Phase C PF
1
1
1
1
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10.
00000
00000

xVAsPF
Total VAs
3Φ PF
Unused
11.
00.000


Hz
Frequency
Unused
Unused
12.
12345
6789A.

+kWh
 Positive
 kWh
Unused
13.
12345
6789A.

-kWh
 Negative
 kWh
Unused
14.
12345
6789A.

+kVARh
 Positive
 kVARh
Unused
15.
12345
6789A.

-kVARh
 Negative
 kVARh
Unused
16.
000.00
000.00

kVAh
VA hours (Most significant half)
VA hours (Least significant half)
Unused
17. 00000
00000

kWh NET
18.
1
00000
00000
0000
xWPFHz
Watt hours Net (Most significant half)
Watt hours Net (Least significant half)
Unused
Total Watts
3Φ PF
Frequency
- Screen available on WYE meters only
x - indicates blank, (k)ilo, (M)ega, or (G)iga
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DEMAND DISPLAY SCREENS
Format
Quantity
19.
000.00
000.00
000.00
Amps Dmd
Phase A Amps Demand
Phase B Amps Demand
Phase C Amps Demand
20.
00000
00000
00000
Amps MAX
Phase A Maximum Amperes Demand
Phase B Maximum Amperes Demand
Phase C Maximum Amperes Demand
21.
000.00
000.00

AmpsDmdR
Residual Amps Demand Maximum
Residual Amps Demand
Unused
22.
000.00
000.00
000.00
xV Avg
Phase A Average Voltage
Phase B Average Voltage
Phase C Average Voltage
23.
00000
00000
00000
xV MAX
Phase A Maximum Volts Demand
Phase B Maximum Volts Demand
Phase C Maximum Volts Demand
24.
00000
00000
00000
xV MIN
Phase A Minimum Volts Demand
Phase B Minimum Volts Demand
Phase C Minimum Volts Demand
25.
000.00
000.00
000.00
xV Avg
Phase A-B Average Voltage
Phase B-C Average Voltage
Phase C-A Average Voltage
26.
00000
00000
00000
xV MAX
Phase A-B Maximum Volts Demand
Phase B-C Maximum Volts Demand
Phase C-A Maximum Volts Demand
27.
00000
00000
00000
xV MIN
Phase A-B Minimum Volts Demand
Phase B-C Minimum Volts Demand
Phase C-A Minimum Volts Demand
28.
00000
00000
00000
xW    
Total Maximum Watt Demand
Total Watts (Also on Screen 7)
Total Minimum Watt Demand
1
1
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29.
00000
00000
00000
xVAR    
Total Maximum VAR Demand
Total VARs (Also on Screen 7)
Total Minimum VAR Demand
30.
00000
00000
00000
xVA    
Total Maximum VAs
Total VAs (Also on Screen 10)
Total Minimum VAs
1
- Screen available on WYE meters only
x - indicates blank, (k)ilo, (M)ega, or (G)iga
HARMONIC SUMMARY DISPLAY SCREENS
Format
Quantity
31.
00000
00000
00000
Fnd Amps
Phase A Fundamental Amperes
Phase B Fundamental Amperes
Phase C Fundamental Amperes
32.
00000


FndN  Amps
Fundamental Residual Amperes
Unused
Unused
33.
00000
00000
00000
Fnd xV
Phase A Fundamental Volts
Phase B Fundamental Volts
Phase C Fundamental Volts
34.
000.00
000.00
000.0
Fnd xV
Phase A-B Fundamental Voltage
Phase B-C Fundamental Voltage
Phase C-A Fundamental Voltage
35.
000.00
000.00
000.00
%TDD I
Phase A Current %Total Demand Distortion (%TDD)
Phase B Current %Total Demand Distortion (%TDD)
Phase C Current %Total Demand Distortion (%TDD)
36.
000.00
000.00
000.00
%THD V
Phase A Voltage %Total Harmonic Distortion (%THD)
Phase B Voltage %Total Harmonic Distortion (%THD)
Phase C Voltage %Total Harmonic Distortion (%THD)
37.
000.00
000.00
000.00
%THD V
Phase A-B Voltage %Total Harmonic Distortion (%THD)
Phase B-C Voltage %Total Harmonic Distortion (%THD)
Phase C-A Voltage %Total Harmonic Distortion (%THD)
38. 00.000
00.000
00.000
K-Factor
1
1
K-Factor Phase A (Current)
K-Factor Phase B (Current)
K-Factor Phase C (Current)
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39.
0.0000
0.0000
0.0000
DispPF Φ
Phase A Displacement PF 1
Phase B Displacement PF
Phase C Displacement PF
40.
00000


DispPF T
3Φ Displacement PF
Unused
Unused
41.
000.00
000.00
000.00
FndDmdIΦ
Phase A Fundamental Demand Amps
Phase B Fundamental Demand Amps
Phase C Fundamental Demand Amps
42.
000.00
000.00
000.00
FndDmdIΦ
Phase A Maximum Fundamental Demand Amps
Phase B Maximum Fundamental Demand Amps
Phase C Maximum Fundamental Demand Amps
43.
000.00
000.00

FundDmdIR
Maximum Fundamental Demand Amps Residual
Fundamental Demand Amps Residual
Unused
44.
000.00
000.00
000.00
xW Avg
Phase A Average Watts
Phase B Average Watts
Phase C Average Watts
45.
000.00
000.00
000.00
xW Max
Phase A Maximum Average Watts
Phase B Maximum Average Watts
Phase C Maximum Average Watts
46.
000.00
000.00
000.00
xW Min
Phase A Minimum Average Watts
Phase B Minimum Average Watts
Phase C Minimum Average Watts
47.
000.00
000.00
000.00
xVAR Avg
Phase A Average VARs
Phase B Average VARs
Phase C Average VARs
User Manual
M65x/EN M/B
M650, M651, M653
Page 37
48.
000.00
000.00
000.00
xVAr Max
Phase A Maximum Average VARs
Phase B Maximum Average VARs
Phase C Maximum Average VARs
49.
000.00
000.00
000.00
xVAR Min
Phase A Minimum Average VARs
Phase B Minimum Average VARs
Phase C Minimum Average VARs
50.
000.00
000.00
000.00
xVA Avg
Phase A Average VAs
Phase B Average VAs
Phase C Average VAs
51.
000.00
000.00
000.00
xVA Max
Phase A Maximum Average VAs
Phase B Maximum Average VAs
Phase C Maximum Average VAs
52.
000.00
000.00
000.00
xVA Min
Phase A Minimum Average VAs
Phase B Minimum Average VAs
Phase C Minimum Average VAs
53.
00000
00000
00000
SecVolts
Phase A Secondary Volts
Phase B Secondary Volts
Phase C Secondary Volts
54.
00000
00000
00000
SecVolts
Phase A-B Secondary Volts
Phase B-C Secondary Volts
Phase C-A Secondary Volts
55.
000.00


V aux
Auxiliary Voltage
Unused
Unused
1
1
- Screen available on WYE meters only
x - indicates blank, (k)ilo, (M)ega, or (G)iga
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M650, M651, M653
M65x/EN M/B
Page 38
The screens that are displayed in the scrolling mode can be programmed
(ENABLED/DISABLED) by the user. This programming can be done by using the front panel
buttons of the device or through the web server.
Enable/Disable Display Mode Screens via the front buttons on Display:
The Screens can be enabled or disabled (refer to Section 5.5) via the front display buttons by
1.6
entering the setup mode section and going to the Screen Enable menu ( , Scrn Ena).
Enable/Disable Display Mode Screens via the Web Server:
The screens can be enabled or disabled via the web server. (Refer to section 5.6) From the
web page, select the Settings tab then click on Screen Enable in the menu list. One screen
each can be selected for the left and right displays on the M653 and for the home screen.
Other screens enabled will be available on the display of the M650 and on the centre display of
the M653.
For all the Watt, VAR and/or PF displays the "SIGN" of the quantity is indicated by the centre
segment of the left most digit, which will be illuminated to produce a "-" for negative quantities.
Positive quantities will have no polarity indication. This restricts the display to 4 digits in the
Watt and/or VAR display, however this is a restriction for the display only, internally the
instrument still carries full precision.
User Manual
M65x/EN M/B
M650, M651, M653
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4.1.1 Overview – Buttons Functions
Figure 5 – Button functions for Display Mode
Figure 6 – Button functions in Set-up Mode
User Manual
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M650, M651, M653
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4.1.2 Keypad Functions for Display Mode
Measurements screens may be stepped through manually by pushing the up and down arrow
keys. Pushing the Toggle (Exit) key turns the scroll function off and on. When the scroll
function is activated, the measurement screens will automatically step through the user-defined
screens. Auto scroll state (ON/OFF) is stored in non-volatile memory. Pressing the Home
(Enter) key will bring up the home screen. The factory default home screen will be Amps A, B,
1.6
C. If a user enables or disables screens via the front display buttons from Setup Mode ( Scrn
st
Ena), then the home screen will automatically become the 1 enabled screen. The home
screen can be setup as any one of the enabled screens by simultaneously pressing the Home
(Enter) and Toggle (Exit) buttons when on the desired screen and can also be done through the
web server Settings tab.
Table 1 –Button Functions
Button
Up Arrow
Display Mode Function
Next measurement/value
Setup Mode Function
Next menu item
Down Arrow
Previous measurement/value
Previous menu item
or
Y (Yes) when prompted
Home (Enter)
Scroll to designated home
screen
Enter selected submenu (or
configuration item), or
Increments the highlighted
digit when entering number,
or
IP address, or
Toggle (Exit)
Toggle Auto Scroll On/Off
EXI
Combination Up and
Exit keys
Enter Setup Mode
Combination Up and
Down Keys
(Resets and configuration
setting are done in the setup
menu)
Resets Demand Values
Combination Home
(Enter) and Toggle
(Exit) keys
Designate the displayed
screen as “Home Screen”
Left Arrow
Copies screen from middle
display to left display
(M653 only)
Right Arrow
Copies screen from middle
display to right display
(M653 only)
Resets are found in the setup menu
N (No) when prompted
Exits current menu selection
and moves up to next higher
menu level.
Returns to display mode on
exit from main setup menu
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M65x/EN M/B
M650, M651, M653
Page 41
4.1.3 Display Error Messages
Error messages from self test are shown on the display. The table below summarizes the errors
and the messages displayed:
SELF TEST RESULT SUMMARY FOR M65x DEVICES
Fault
Display
Overflow
Fault
Indication
Display
flashes
9999
Input gain
calibration
checksum error
G CAL
Input phase
calibration
checksum error
P CAL
Analog outputs
calibration
checksum error
A CAL
Input OverRange
CLIP
Protocol
Configuration
Error
P CFG
Firmware
Download in
Progress
FLASH
Effects of Fault
Corrective Action
Measured quantity is too large to be
displayed. Communication option
output may still be accurate, if
overload does not exceed meter
input ratings
Calibration constants for the input
gain are in error. The display and
the communication option output are
reduced in accuracy to
approximately +/-3%.
Calibration constants for the phase
are in error. The display and the
communication option output are
reduced in accuracy to
approximately +/-3%.
Calibration constants for the
analogue outputs are in error. The
analogue output option is reduced in
accuracy to approximately +/-3%.
Peak input quantity exceeds the
range of the instrument. Both
display and communication option
output accuracy reduced by an
amount depending upon the degree
of over-range.
Instrument protocol configuration
may be corrupted and inaccurate.
This may cause communication
errors.
Will be displayed during download
and will disappear shortly after user
reboots meter
Correct fault
external to
instrument.
Return to factory
for repair
Return to factory
for repair
Return to factory
for repair
Verify input
signals are within
range. If within
range, return to
factory for repair.
Reset
configuration.
Reboot meter
when prompted.
User Manual
M653/EN M/A
M653
Page 42
4.2 Serial Port
This port when ordered can be set to RS-232 or RS-485, and support baud rates up to 115200.
Set-up of the Serial Port can be accomplished by using a web browser connected to the
1.4
Ethernet port, or via the front display buttons (Setup menu - Serial). The default configuration
for the serial ports is:
Serial Port Default Setting
Port
Protocol
Parity
Baud
IED
Address
Physical Media
Serial
DNP 3
None
9600
1
RS-232
Serial cable requirements for RS485 connection:
Tie RS-485 cable shields (pin 15) to earth ground at one point in system.
The recommended torque ratings for the terminal block wire fasteners are listed in the Physical
Specifications table (section 1.3).
Transient Voltage Suppressor (TVS) clamp devices are used on the serial port as the method of
protection. The serial port is clamped to a voltage of 16.7-18.5V nominal, 24.46V max. The
clamps are rated for a peak pulse current of 24.6 max.
4.2.1 RS485 Connections
Note that various protocols and services have different port connection requirements. When
making connections to serial ports for Modbus or DNP3 over RS485, 2-wire half duplex is
required. This is because it is imperative to maintain a minimum time period (3 1/3 characters)
from the time the transmitter shuts off to the next message on the bus in order to guarantee
reliable communications. See figure 7 below for RS485 cable wiring diagrams.
Figure 7 - Typical RS-485 Cable Wiring
User Manual
M65x/EN M/B
M650, M651, M653
Page 43
Figure 8 – RS-232 Cable Wiring Diagram
User Manual
M65x/EN M/B
M650, M651, M653
Page 44
5.0 FUNCTIONAL DESCRIPTION
5.1 Configuration
Setup of the M65x meters is most easily performed using the web interface via the Ethernet
service port. Basic configuration can also be done from the front display of the M650 and M653
by entering the setup mode.
5.2 HTML Web Server
The M65x incorporates an internet compatible HTML web page.
5.3 Passwords
Passwords can be setup through the web interface in the M65x for use in controlling access to
configuration and other functions available through the Ethernet port or the front panel display.
Passwords may be comprised of the 95 printable ASCII characters as defined by
http://en.wikipedia.org/wiki/ASCII#ASCII_printable_characters which includes 0-9, a-z, A-Z, and
special characters. Passwords may have maximum length of 20 characters and a minimum of 1
character. Passwords prompts are disabled by leaving the new password field blank and
clicking the 'Change Password' button. The default password from the factory is to have no
password set.
The password is used to authenticate a session when prompted. The session authentication
will last until the user clicks the 'Log Out' link on the upper right corner of the Web Interface or
after five minutes elapses. Authentication will be required when attempting the following
actions:
Resetting demand and energy values on the Web Interface Resets page
Applying changes to any settings on the Web Interface Settings tab
Uploading new firmware on the Firmware Upload page
Changing the password on the Password Security page
Rebooting the IED
The Password Security page includes the Front Panel Configuration Lock, which may be used
to prevent access to the following actions (not M651):
Setup Mode on the Front Panel (see section 5.5)
Demand Resets from the Front Panel (section 6.9.4).
Home Screen selection from the Front Panel (section 4.1.2)
If these options are attempted while the lock is enabled, the message 'Locked' will be briefly
displayed on the front panel alphanumeric display for M65x.
User Manual
M650, M651, M653
5.4 Navigating the M65x’s setup menu from the front panel
M65x/EN M/B
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M65x/EN M/B
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M65x/EN M/B
Page 49
User Manual
M65x/EN M/B
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How to Enter an Integer:
Increment highlighted digit by 1.
Highlight Previous/Next digit.
Exit to menu
How to Enter a Floating Point Number:
Increment highlighted digit by 1.
Shifts decimal point one place to right. Decimal moves to leftmost digit when right-most digit is passed.
Highlight Next digit. Highlights left-most digit when right-most
digit is passed.
Exit to menu
How to Enter an IP address:
Increment highlighted digit by 1.
Highlight Previous/Next digit. Numbers scroll left and right
to follow highlighted digit.
Exit to Network menu
Page 50
User Manual
M65x/EN M/B
M650, M651, M653
Page 51
5.5 Performing set-up through the web page interface
This section will assume you are able to use the factory default IP address of 192.168.0.171 to
connect to the web page using an HTML web server. If this is not the case you may need to
refer to section 3.5.1 (Network settings) and the previous section (Navigating the M65x’s setup
menu from the Front panel) to change your network configuration settings.
Enter the M65x’s IP address into your internet browser to connect with the M65x web page
interface. Internet browsers supported are Firefox, Internet Explorer, Safari and Google
Chrome. The Home page screen should appear as shown below.
Home page:
From the home screen you can select from the following tabs:
Data – This page displays current data measurements
Resets – This page allows certain quantities to be reset
Settings – This page allows the user to change the configuration settings. Making M65x
configuration changes require the unit to be rebooted. Configuration settings for the M65x are
stored in flash memory.
Contact – This page indicates how to contact Alstom Grid
NOTE: Some screen shots shown below may not exactly match the appearance of those from
your actual meter.
User Manual
M650, M651, M653
Data page: Two views – Instantaneous and Demands
M65x/EN M/B
Page 52
User Manual
M65x/EN M/B
M650, M651, M653
Resets page: From this page select the quantity to be reset and click apply
Settings page: Click on one of the settings categories (Identity, Input, Network, Serial Port,
Protocol, Screen Enable, Custom Screens, Load/Store Settings, Password Security, or
Firmware Upload) to be taken to the next page.
Contact Page:
Page 53
User Manual
M65x/EN M/B
M650, M651, M653
Page 54
Settings Page Selections:
From the Settings page screen you can select one of the following selections:
Identity– This page allows the user to enter information that is necessary to identify the meter. It
gives an identity to a particular M65x. Each M65x should have different information entered for
its identity.
Input – This page allows for the selection of wiring configuration, setup of CT and PT ratios,
demand intervals, and TDD denominator.
Network – This page allows the user to change the network configuration settings for IP
address, gateway and router address.
Serial Port – This page allows user configuration for the serial port settings. Note that if no
serial port is ordered this setting won’t appear and if the transducer output option is selected
then that setting will replace serial.
Protocol – This page allows user configuration of the protocols – DNP or Modbus
Screen Enable - Allows the screens shown on the M65x display (front panel) to be enabled or
disabled by the user. (Not applicable for M651)
Custom Screens – Allows the user to set up custom display screens if the standard screens
don’t meet their needs. (Not applicable for M651)
Load/Store Settings – This page allows you to save and retrieve settings for the M65x meter
Password Security – This page allows the user to set a password and to enable or disable
access to front display configuration.
Firmware Upload – This page allows the user an interface to browse for or type in the location
on their PC of new firmware for purposes of uploading to the unit.
Screen shots showing the selections to be made for each of the above selections follow on the
next few pages. Default values are shown where applicable.
M65x configuration changes require the unit to be rebooted. Configuration settings for the
M65x are stored in flash memory.
User Manual
M650, M651, M653
Identity:
Input:
M65x/EN M/B
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User Manual
M650, M651, M653
Network:
Serial Port (if option ordered):
Analogue Output (if option ordered):
M65x/EN M/B
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User Manual
M65x/EN M/B
M650, M651, M653
Page 57
Protocol Selection (if Option ordered):
First select between Modbus or DNP3. You will then select Optimal Resolution (default) or
Primary Units. Next you will choose a session. Under Type, there will be 4 different selections
for Modbus and 3 for DNP3. Under Modbus the options are Disabled, TCP, ASCII, or RTU. For
DNP3 the selections are Disabled, Serial, or TCP. Under DNP3, clicking on the Advanced
button reveals more advanced functions that may or may not need to be changed. Clicking on
the Basic button hides the advanced functions. A detailed description of the setup parameters
for Modbus and DNP3 can be found in the Appendix of the respective protocol manuals.
There are both fixed and configurable register/point lists. Please refer to the appropriate
protocol manual for more information regarding how to view or edit the register/point list.
Modbus
DNP3
User Manual
M65x/EN M/B
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DNP Serial
Page 58
DNP TCP
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Page 59
Modbus RTU
Modbus TCP
User Manual
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Screen Enable: (not M651)
M65x/EN M/B
Page 60
User Manual
M65x/EN M/B
M650, M651, M653
Page 61
Custom Display Screen Settings: Two Sections – Build/Edit and Summary
The Custom Display Screen Configuration page contains two sections: the Build/Edit panel and
the Summary panel. One custom display screen is built at a time in the Build/Edit panel and is
then added to the Summary panel, which presents a list of all the custom screens that have
been built. The Build/Edit panel is presented if there are no custom screens stored on the IED
when the page is loaded; otherwise, the Summary panel is presented. Only one panel is visible
at a time.
Build/Edit panel
Select a measurement to be displayed on each display line from the dropdown lists and enter
an alphanumeric label that describes the display screen.
Special character buttons insert the characters shown on the buttons into the “Label” field. The
“k/M/G” (kilo/Mega/Giga) button inserts an underscore character into the “Label” field, which is
automatically replaced with the appropriate unit prefix when displayed on the IED’s front panel.
The dot character is used to separate parts of a single label into multiple labels that apply to the
different display lines. It is necessary to place dots between underscore that apply to different
display lines.
The MIN, MAX, AVG, line and phase LEDs are automatically lit by the IED, based on the
selected measurements.
Click the “Next >” button to view the summary panel.
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M65x/EN M/B
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Summary panel:
Screens are saved to IED once the “Apply” button has been clicked. A row (screen) from the
summary table can be selected for viewing, editing or deleting by clicking its radio button.
The order of the screens can be changed by selecting a screen from the list and clicking on the
up or down arrows.
Load/Store Device Settings:
User Manual
M650, M651, M653
Password Security Settings:
Firmware Upload:
M65x/EN M/B
Page 63
User Manual
M650, M651, M653
M65x/EN M/B
Page 64
6.0 MEASUREMENTS
Basic measurement quantities are calculated and updated every 100ms. These quantities
include RMS Amperes and RMS Volts, Watts, VARs, VAs, Power Factor, all harmonic-based
measurements (such as fundamental-only quantities), Energy, and Frequency, and Phase
Angle.
Note: For all of the following measurements, it is important to keep in mind that the specific
protocol used to access the data may affect the data that is available, or the format of that data.
No attempt is made here to describe the method of accessing measurements - always check
the appropriate protocol manual for details.
6.1 Changing Transformer Ratios
The M65x has the capability to store values for Current Transformer (CT) and Potential
Transformer (VT) turns ratios. The VT and CT values are factory set to 1:1 CT and 1:1 VT.
These values can be entered into the M65x over the network or via front display buttons or web
page, and will be stored in internal non-volatile memory. All measurements are presented in
primary units, based on these ratios. Please note that the value entered via the front display
should be the result of the division of the primary value by 5. For example for a ratio of 6000:5,
you would enter a value of 1200 through the front display. The web interface allows you to
choose either 1A or 5A for the denominator, and the primary value is entered directly. The PT
ratio is to 1 when entering through the front display. The web allows other denominators (110,
115, or 120) to be used. Refer to the appropriate protocol manual for more information on
changing transformer ratios.
6.2 Current
The M65x has three current inputs, with an internal CT on each channel except in the case
where external split-core CTs are used. These inputs can read to 2x nominal (2A RMS for 1A
input, 10A RMS for 5A input (symmetrical)) under all temperature and input frequency conditions.
No range switching is used, allowing a high dynamic range.
The current signals are transformer coupled, providing a true differential current signal.
Additionally, a continuous DC removal is performed on all current inputs. Instrument
Transformer Ratios can be entered for each current input, as described above.
6.2.1 Residual Current
The M65x calculates the vector sum of the three phase currents, which is known as the
Residual Current. The Residual Current is equivalent to routing the common current return wire
through the neutral current input on systems without separate current returns for each phase.
6.3 Voltage Channels
All voltage inputs are measured relative to a common reference level (essentially panel ground).
See Appendix 1 for input connection information. Common mode signals can be removed by
signal processing algorithms, instead of the more traditional difference amplifier approach. This
greatly simplifies the external analogue circuitry, increases the accuracy, and allows
measurement of the Neutral-to-Ground voltage at the panel. The 7kV input divider resistors are
accurate to within +/- 25ppm/°C, and have a range of 400V PEAK , from any input to panel ground.
Each sample is corrected for gain using factory calibration values stored in non-volatile memory
on the board. Additionally, a continuous DC removal is performed on all inputs.
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M65x/EN M/B
M650, M651, M653
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The advantages of this method of voltage measurement are apparent when the M65x is used
on the common 2, 2½, and 3 element systems (refer to Section 6.6). The M65x is always
calculating Line-to-Neutral, and Line-to-Line voltages with equal accuracy. On 2 element
connections, any phase can serve as the reference phase.
On 2½ element systems, one of the phase-to-neutral voltages is missing, and the M65x must
create it from the vector sum of the other two phase-to-neutral voltages. In order to configure
the M65x for 2½ element mode and which phase voltage is missing, select one of the following:
2.5 element - A, 2.5 element - B, or 2.5 element – C.
6.4 Voltage Aux
The M65x provides a measurement for the voltage connected to the power supply terminals.
This is a differential voltage. The value can be AC or DC depending upon the power supply
voltage source.
6.5 Power Factor
The per-phase Power Factor measurement is calculated using the "Power Triangle", or the
per-phase WATTS divided by the per-phase VAs. The Total PF is similar, but uses the Total
WATTS and Total VAs instead. The sign convention for Power Factor is shown in Figure 9.
6.6 Watts / Volt-Amperes (VAs) / VARs
On any power connection type (2, 2½, and 3 element), the M65x calculates per-element Watts
by multiplying the voltage and current samples of that element together. This represents the dot
product of the voltage and current vectors, or the true Watts. The per-element VAs are
calculated from the product of the per-element Volts and Amps. The per-element VARs are
calculated from fundamental VARs.
In any connection type, the Total Watts and Total VARs is the arithmetic sum of the per-element
Watts and VARs. The sign conventions are shown in Figure 9.
When used on 2-element systems, the reference phase voltage (typically phase B) input, is
connected to the Neutral voltage input, and effectively causes one of the elements to be zero. It
is not required to use any particular voltage phase as the reference on 2-element
systems. When used on 2-element systems the per-element Watts, VARs, and VAs have
no direct physical meaning, as they would on 2½ and 3 element systems where they
represent the per-phase Watts, VARs, and VAs.
When used on 2½ element systems, one of the phase-to-neutral voltages is fabricated, as
described in Section 6.3. In all other respects, the 2½ element connection is identical to the 3
element connection.
6.6.1 Geometric VA Calculations
GEOMETRIC VATOTAL  WattsTOTAL  VARsTOTAL
2
2
This is the traditional definition of Total VAs for WYE or DELTA systems, and is the default
method for Total VAs calculation. The value of Total VAs calculated using this method does not
change on systems with amplitude imbalance, relative to a balanced system.
There is also a relationship to the Total Power Factor, which is described in Section 6.5. Total
Power Factor calculations using the Geometric VA method will still indicate a "1" on a system
with phase amplitude imbalance, or cancelling leading and lagging loads.
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For example, on a system with a lagging load on one phase and an equal leading load on
another phase, the Geometric VA result will be reduced relative to a balanced system but the
Total Power Factor will still be "1".
Figure 9 - Sign Conventions for Power Measurements
(P is Power, Q is VARS and S is VA)
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M65x/EN M/B
M650, M651, M653
Page 67
6.7 Compensated Watts and VARs (Line and Transformer Loss Compensation)
The total Watt and Var losses can be calculated using five user entered parameters and
measured current and voltage values. These losses are added or subtracted to/from the
measured Total Watts and Total Vars when accumulating Energy.
Loss compensation on the M65x takes the following general form:
2
2
2
4
P COM = P UNC + A·I + B·V + E·P UNC
Q COM = Q UNC + C·I + D·V + E·Q UNC
Where:
P COM
P UNC
Q COM
Q UNC
I
V
A
B
C
D
E
Compensated three-phase total watts. Note the accumulators for +kWh and –
kWh in the M65x are calculated by integrating the P COM measurement over time.
Uncompensated three-phase total watts measured at the point where the meter is
connected.
Compensated three-phase total VARs. Note the accumulators for +kVARh and –
kVARh in the M65x are calculated by integrating the Q COM measurement over
time.
Uncompensated three-phase total VARs measured at the point where the meter is
connected.
RMS line current measured at the point where the meter is connected.
RMS line-line voltage measured at the point where the meter is connected.
Meter setting that accounts for the sum of the full-load-watt-losses from all
sources.
Meter setting that accounts for the transformer’s no-load-watt-losses.
Meter setting that accounts for the sum of the full-load-VAR-losses from all
sources.
Meter setting that accounts for the transformer’s no-load-VAR-losses.
Meter setting that accounts for any “system” losses, proportional to the
uncompensated power.
Configuring the meter to perform loss compensation simply requires the user to calculate the
coefficients A, B, C, D, and E defined above, and enter them in the appropriate fields in the
M65x’s webserver interface on the Settings/Input page as shown in the screen shot below
The sign of the settings A, B, C, D, and E determines whether losses will be added to or
subtracted from the uncompensated measurements in order to determine the compensated
power and energy. To add losses, be sure the settings are all positive. To subtract losses, be
sure the settings are all negative. Settings should always have the same sign.
Making all of the settings equal to zero turns off loss compensation.
System losses (E) are a fixed percentage, mutually agreed upon between two electric utilities,
about an interchange point that lies on a branched line. As such, E is not a physical property of
any particular line, transformer or the meter, so no further guidance on how best to calculate the
coefficient E can be provided here. All instructions following will be concerned only with the
calculation of the coefficients A, B, C, and D. Users who do not intend to use system losses
should simply set E equal to zero.
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M65x/EN M/B
M650, M651, M653
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6.8 Energy
Separate values are maintained for both positive and negative Watt-hours, positive and
negative VAR-hours, and VA-hours, for each feeder. These energy quantities are calculated
every cycle from the Total Watts, Total VARs, and Total VAs, and the values are stored into
non-volatile memory every 15 seconds. Energy values may be reset. All values are reset
simultaneously. Refer to the appropriate protocol manual for details.
6.9 Frequency
The M65x monitors the change in Phase Angle per unit time using the Phase Angle
measurement for the fundamental generated by the FFT. The System Frequency is the
frequency of the input used for synchronizing the sampling rate.
6.10 Demand Measurements
The traditional thermal demand meter displays a value that represents the logarithmic response
of a heating element in the instrument driven by the applied signal. The most positive value
since the last instrument reset is known as the maximum demand (or peak demand) and the
lowest value since the last instrument reset is known as the minimum demand. Since thermal
demand is a heating and cooling phenomenon, the demand value has a response time T,
defined as the time for the demand function to change 90% of the difference between the
applied signal and the initial demand value. For utility applications, the traditional value of T is
15 minutes, although the M65x can accommodate other demand intervals (Section 6.9.5).
The M65x generates a demand value using modern microprocessor technology in place of
heating and cooling circuits, it is therefore much more accurate and repeatable over a wide
range of input values. In operation, the M65x continuously samples the basic measured
quantities, and digitally integrates the samples with a time constant T to obtain the demand
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value. The calculated demand value is continuously checked against the previous maximum
and minimum demand values. This process continues indefinitely, until the demand is reset or
until the meter is reset (or power removed and reapplied). The demand reset and power up
algorithms are different for each measurement. These routines are further described in
following paragraphs. The maximum and minimum demand values are stored in non-volatile
memory on the Host Processor module.
NOTE:
Changing VT or CT ratios does NOT reset demand measurements to zero.
Demand Quantity
Phase Reference
Function
Amperes
Phase, Residual
Present, Max
Fundamental Amperes
Phase, Residual
Present, Max
Volts
Phase - Neutral, Phase Phase
Present, Max, Min
Total Watts (A, B, C, Total)
Phase, Total
Present, Max, Min
Total VARs (A, B, C, Total)
Phase, Total
Present, Max, Min
Total VAs (A, B, C, Total)
Phase, Total
Present, Max, Min
6.10.1 Ampere and Fundamental Ampere Demand
Present Ampere Demands are calculated via the instantaneous measurement data used to
calculate the per-phase Amperes.
Upon power up, all Present Ampere Demands are reset to zero. Maximum Ampere Demands
are initialized to the maximum values recalled from non-volatile memory. Upon Ampere
Demand Reset, all per-phase Present and Maximum Ampere Demands are set to zero. When
Ampere Demands are reset, Fundamental Current Demands are also reset.
6.10.2 Volt Demand
Present Volt Demands are calculated via the instantaneous measurement data used to
calculate the per-phase Volts. Upon power-up all Present Volt Demands are reset to zero. The
Maximum Volt Demands and Minimum Volt Demands are initialized to the minimum and
maximum values recalled from non-volatile memory. In order to prevent the recording of false
minimums a new Minimum Volt Demand will not be stored unless two criteria are met. First, the
instantaneous voltage for that particular phase must be greater than 20V rms (secondary).
Second, the Present Demand for that particular phase must have dipped (Present Demand
value must be less than previous Present Demand value). Upon Voltage Demand Reset, all
per-phase Maximum Voltage Demands are set to zero. Minimum Voltage Demands are set to
full-scale.
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6.10.3 Power Demands (Total Watts, VARs, and VAs)
Present Total Watt, VAR, and VA Demands are calculated via the instantaneous measurement
data. The Total VA Demand calculation type is based on the instantaneous Total VA
calculation type (Section 6.6)
Upon power-up, all Present Total Watt, VAR, and VA Demands are reset to the average of the
stored Maximum and Minimum values. The Maximum and Minimum Demands are initialized to
the minimum and maximum values recalled from non-volatile memory. Upon a demand reset,
the Maximum and Minimum Demands are set equal to the Present Total Watt, VAR, and VA
Demand values. A demand reset does not change the value of the Present Total Watt, VAR,
and VA Demands.
6.10.4 Demand Resets
The demand values are reset in 3 groups: current, voltage, and power. This can be
accomplished via the front display or from a web browser.
6.10.5 Demand Interval
The M65x uses 900 seconds (15 minutes) as the default demand interval for current. The
default for average volts and average power measurements is 60 seconds. Three separate,
independent demand intervals may be set for current, voltage, and power. The range of
demand intervals is 10 to 9999 seconds. These settings can be accomplished by using the
front display or web server setup.
6.11 Harmonic Measurements
All harmonic and harmonic related measurements are calculated every 100 ms. In the
following sections, Harmonic 0 indicates DC, Harmonic 1 indicates the fundamental, and
Harmonic N is the nth multiple of the fundamental.
6.11.1 Voltage Distortion (THD)
Voltage Harmonic Distortion is measured by phase in several different
ways. The equation for Total Harmonic Distortion (THD) is given in
Equation 1. Note the denominator is the fundamental magnitude.
63
%T H D 
V
h 2
2
h
V1
 1 00%
Equation 1 - Voltage THD
6.11.2 Current Distortion (THD and TDD)
Current Harmonic Distortion is measured by phase in several different
ways. The first method is Total Harmonic Distortion (THD). The
equation for THD is given in Equation
2. Note the denominator is the fundamental magnitude.
63
%T H D 

h 2
I1
I h2
 1 00%
Equation 2 - Current THD
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Alternatively, Current Harmonic Distortion can be measured as
63
Demand Distortion, as defined by IEEE-519/519A. Demand
I h2
Distortion differs from traditional Harmonic Distortion in that the
denominator
%T D D  h  2
 100%
of the distortion equation is a fixed value. This fixed
IL
denominator value is defined as the average monthly
Equation 3 – Current TDD
peak demand. By creating a measurement that is based
on a fixed value, TDD is a "better" measure of distortion
problems. Traditional THD is determined on the ratio of harmonics to the fundamental. While
this is acceptable for voltage measurements, where the fundamental only varies slightly, it is
ineffective for current measurements since the fundamental varies over a wide range. Using
traditional THD, 30% THD may mean a 1 Amp load with 30% Distortion, or a 100 Amp load with
30% Distortion. By using TDD, these same two loads would exhibit 0.3% TDD for the 1 Amp
load and 30% TDD for the 100 Amp load (if the Denominator was set at 100 Amps). In the
M65x, Current Demand Distortion is implemented using Equation 3. The TDD equation is
similar to Harmonic Distortion (Equation 2), except that the denominator in the equation is a
user-defined number. This number, I L , is meant to represent the average load on the system.
The denominator I L is different for each phase and neutral, and is set by changing the
denominator values within the M65x.

Note that in Equation 3, if I L equals the fundamental, this Equation becomes Equation 2 Harmonic Distortion. In the instrument this can be achieved by setting the denominator to zero
amps, in which case the instrument will substitute the fundamental, and calculate Current THD.
Note that there is a separate, writeable denominator for each current input channel. The TDD
Denominator Registers are set by the factory to 5 Amps (secondary), which is the nominal full
load of the CT input with a 1:1 CT. These writeable denominators can be used in conjunction
with the distortion measurements to obtain the magnitudes of harmonics, in other words,
convert from percent to amps. This is simply done by multiplying the percent TDD by the TDD
Denominator for that phase, and the result will be the actual RMS magnitude of the selected
harmonic(s). This technique can also be used if the THD mode (denominator set to zero) is
used, by multiplying the percent THD by the Fundamental Amps for that phase.
6.11.3 Fundamental Current
Fundamental Amps are the nominal component (50/60 Hz) of the waveform. The M65x
measures the magnitude of the fundamental amps for each phase. These measurements can
be used in conjunction with the distortion measurements to obtain the magnitudes of harmonics,
in other words, convert from percent to amps. As was mentioned previously, this is simply done
by multiplying the percent THD by the Fundamental Amps for that phase (which is the
denominator), and the result will be the actual RMS magnitude of the selected harmonic.
6.11.4 Fundamental Voltage
Fundamental Volts are the nominal component (50/60Hz) of the waveform. The M65x
measures the magnitude of the fundamental phase-to-neutral and phase-to-phase volts. These
measurements can be used in conjunction with the distortion measurements to obtain the
magnitudes of harmonics, in other words, convert from percent to volts. This is simply done by
multiplying the percent THD by the Fundamental Volts for that phase (which is the
denominator), and the result will be the actual RMS magnitude of the selected harmonic.
Fundamental Volts and Amps can be used in conjunction to obtain Fundamental VAs, and when
used with Displacement Power Factor can yield Fundamental Watts and Fundamental VARs.
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6.11.5 K-Factor
K-Factor is a measure of the heating effects on transformers, and it is
defined in ANSI/IEEE C57.110-1986. Equation 4 is used by the
M65x to determine K-Factor, where "h" is the harmonic number and
th
"I h " is the magnitude of the h harmonic. K-Factor is measured on
each of the three phases of amps, however there is no
63
K  Factor 
I
h 1
2
h
 h2
63
I
h 1
2
h
"Total" K-Factor. K-Factor, like THD and PF, does not
indicate the actual load on a device, since all three of these measurements
Equation 4 - K-Factor
are ratios. Given the same harmonic ratio, the calculated K-Factor for a
lightly loaded transformer will be the same as the calculated K-Factor for a heavily loaded
transformer, although the actual heating on the transformer will be significantly different.
6.11.6 Displacement Power Factor
Displacement Power Factor is defined as the cosine of the angle (phi) between the
Fundamental Voltage Vector and the Fundamental Current Vector. The sign convention for
Displacement Power Factor is the same as for Power Factor, shown in Figure 9.
The Total Displacement Power Factor measurement is calculated using the "Power Triangle", or
the three-phase Fundamental WATTS divided by the three-phase Fundamental VAs. The perphase Fundamental VA measurement is calculated from the product of the per-phase
Fundamental Amp and Fundamental Volts values. The three-phase Fundamental VA
measurement is the sum of the per-phase Fundamental VA values (Arithmetic VAs).
6.11.7 Phase Angles
The M65x measures the Fundamental Phase Angles for all Currents, Line-to-Neutral Voltages,
and Line-to-Line Voltages. The Phase Angles are in degrees, and all are referenced to the V A-N
Voltage, which places all Phase Angles in a common reference system. Values are from -180
to +180 Degrees. Note that the phase angles are only available in the TUC register set and use
calculation type T8 (see Modbus and DNP3 Protocol manuals for more detail). As with other
measurements, the Phase angles can be mapped to analogue outputs or used in custom
display screens.
6.12 Heartbeat and Health Check
M65x meters provide a Heartbeat State Counter Register that allows the user to determine the
time between successive polls. This counter will increment by the number of milliseconds that
have elapsed since the last time the data was updated. Another use of this register is as a
visual indicator that the data is changing; it allows users of certain MMIs to identify disruption in
the polling of the instrument. The Heartbeat State Counter is a full 32-bit counter that rolls over
at 4,294,967,295 (4,294,967 seconds). The counter starts at zero on power up, and is NOT
stored in non-volatile memory.
M65x meters have several self-tests built in to ensure that the instrument is performing
accurately. The results of these self-tests are available in the Health Check register which is a
simple 16-bit binary value. Each bit represents the results of a particular self-test, with "0"
indicating the test was passed, and "1" indicating the test was failed. If Health status failures
occur, the meter may have experienced an operational failure. The table below provides a
reference of error codes. The Health Check value shown in the M65x web live data page is a
hexadecimal representation of the binary value. For example, a Health Check value of 0000
0014 is the equivalent of the binary value 000000000010100. The “1” shown in bit 2 and bit 4
represents a failed test in those bits which indicates a checksum error for both the gain and
phase on the calibration. Contact the factory for further instructions.
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Health Check Error Codes
Bit
Description
0
Checksum error on analogue output (either 0-1mA or 4-20mA) calibration
constants
2
Checksum error on gain calibration of inputs
4
Checksum error on phase calibration of inputs
12
Indicates firmware download in progress and measurements are offline
6.13 List of Available Measurements & Settings
Available Measurements
Amps A, B, C, Residual
Average Volts AN, BN, CN, AB, BC, CA
Average (Max.) Volts AN, BN, CN, AB, BC, CA
Average (Min.) Volts AN, BN, CN, AB, BC, CA
Average Watts A, B, C, Total
Average (Max.) Watts A, B, C, Total
Average (Min.) Watts A, B, C, Total
Average VARs A, B, C, Total
Average (Max.) VARs A, B, C, Total
Average (Min.) VARs A, B, C, Total
Average VAs A, B, C, Total
Average (Max.) VAs A, B, C, Total
Average (Min.) VAs A, B, C, Total
Class 0 Response Setup
CT Scale Factor
CT Scale Factor Divisor
Demand (Max.) Amps A, B, C, Residual
Demand (Max.) Fund. Amps A, B, C, Residual
Demand Amps A, B, C, Residual
Demand Fundamental Amps A, B, C, Residual
Displacement Power Factor A, B, C
Displacement Power Factor Total
Factory Version Hardware
Factory Version Software
Frequency
Fund. Amps A, B, C, Residual
Fund. Volts AN, BN, CN, AB, BC, CA
Health
Heartbeat
K-factor Amps A
K-factor Amps B
K-factor Amps C
K-factor Amps Residual
Meter Type
Phase Angle Amps A, B, C
Phase Angle Volts A, B, C
Phase Angle Volts AB, BC, CA
Power Factor A, B, C, Total
Protocol Version
PT Scale Factor
PT Scale Factor Divisor
TDD Amps A, B, C, Residual
TDD Denominator A, B, C,
THD Volts AN, BN, CN, AB, BC, CA
VA-Hrs
VAR-Hrs Lag
VAR-Hrs Lead
VARs A, B, C, Total
VAs A, B, C, Total
Volts AN, BN, CN, AB, BC, CA
Volts Aux
Watt-Hrs Net
Watt-Hrs Normal
Watt-Hrs Reverse
Watts A, B, C, Total
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6.14 Calibration
Routine re-calibration is not recommended or required. A field calibration check every few
years is a good assurance of proper operation.
6.15 Instantaneous Measurement Principles
The M65x measures all signals at an effective rate of 64 samples/cycle, accommodating
fundamental signal frequencies from 45 to 65Hz. Samples of all bus signals are taken using a
16-Bit A/D converter, effectively creating 64 "snapshots" of the system voltage and current per
cycle.
6.15.1 Sampling Rate and System Frequency
The sampling rate is synchronized to the frequency of any of the bus voltages prioritized as
follows: V1 A-N , V1 B-N , V1 C-N . This is the frequency reported as the "System Frequency". The
sampling rate is the same for all channels.
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7.0 ANALOGUE OUTPUT OPTION
7.1 Introduction
The Analogue Output options (0 -1 mA or 4-20 mA) feature 3 separate outputs each with two
terminals, one of which is common to all three outputs and which provides a unique return path
for each output.
7.2 Specifications
Outputs:
3 bi-directional, 0-1mA (active) or 4-20mA (loop powered, passive)
0 – 1mA Current Range
Output Range:
Resolution:
Output Resistance:
0 to +/-1mA into 10K ohms or less; Overload to
+/-2.1mA into 5K ohms or less.
0.22uA
500 ohm
4 – 20mA Current Range
Output Range:
Resolution:
Max Loop Voltage:
Max Voltage Drop:
4 to 20mA
1.1uA
40Vdc
2.3V @ 20mA
4 – 20mA Internal Loop Supply
Max Output Voltage:
6V @ 60mA,
Accuracy:
0.25% of Full Scale Input
Data Update Rate (poll rate):
100ms minimum
Input Capacitance, any Terminal to Case:
470pF
7.3 Connections
The connections for the 0-1 mA output option are shown in figure 10 while the connections for
the 4-20 mA with external and internal loop are shown in figure 11.
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Figure 10 – 0-1mA Transducer Output Connections
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Figure 11 – 4-20mA Transducer Output Connections
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8.0 SPLIT-CORE CT INPUT OPTION
8.1 Introduction
A version of the M65x can be supplied with split-core CTs for monitoring the 5A secondary
wiring of an installed CT. This M65x version is customised to operate with the supplied splitcore CTs and cannot be connected to standard 1A or 5A CT outputs, doing so will result in
damage of the M65x.
The split-core CTs are only for installation on the secondary wiring of an installed CT, which are
energized to no more than 600Vac, they cannot be mounted on a load current carrying
conductor (primary). The split-core CTs are designed for monitoring a 5A nominal current with a
maximum current of 10A with rated accuracy. The split-core CTs are not suitable for monitoring
CTs with a 1A secondary.
The split-core CT output is 0 – 10mA and the output is protected by zener diodes to ensure that
it is safe to operate with the secondary leads open circuit.
During manufacture each split-core CT is calibrated to linearise both the amplitude and phase
angle response. The split-core CTs are supplied labelled with the serial number of a specific
M65x and the specific phase on that unit. They must be connected to the specified phase on
the specific M65x unit if the defined accuracy specification of the measurements is to be
achieved.
8.2 Mounting
The M65x supplied with the split-core CTs is mounted in the same way as the standard M65x,
as defined in section 2.
The split-core CTs have the following dimensions.
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The split-core CTs can be mounted in optional brackets, side and end mounted versions are
available, they are held in the bracket by 2 screws. The brackets can be mounted on any flat
surface.
End Mounting
Side Mounting
8.3 Rear Panel and Wiring
The M65x version for use with split-core CTs is fitted with screw terminals for the current
connections rather than the studs fitted on the standard version. All other wiring details are the
same as the standard M65x and are defined in section 3. See Appendix A1 for the detailed
wiring diagrams of the split-core version.
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The split-core CTs are fitted around the secondary cabling of the installed CT as shown below,
The gate of the core is fastened using 2 bolts which should not be overtightened. It is important
that the mating faces of the core are free on any dirt or debris which could prevent the lapped
faces of the CT mating correctly.
The split-core CT is supplied as standard with 2.4m (8ft) of cable attached, this can be extended
during installation by a reasonable amount. Any length of wire that adds less than 1.0 Ohm to
the total loop resistance from the split-core CT to the M65x can be added without degrading the
accuracy. For example: Remember, there are two leads for each CT. So if you want to add
20m to the distance between the M65x and the CT, you are adding the effect of two 20m
lengths of wire, or 40m to the loop resistance. Therefore use a wire gauge and composition that
has less than 1.0 Ohm resistance per 40m.
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APPENDIX
A1 CT/VT Connection Diagrams
Please note that there is an option on the Settings/Input page to invert the CT Polarity (see
screen shot clip below). This option is the equivalent of swapping the connections in the
connection diagrams below at the HI and LO terminals for each CT input, that is, swapping 7
and 10, 8 and 11, 9 and 12. The effect is a 180 degree phase shift in the current signals.
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Figure 12 - Signal Connections – M65x
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Figure 12 - Signal Connections – M65x
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Figure 13 – M65x External Split-Core Signal Connections
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A2 Ethernet Troubleshooting
If the Link LED fails to illuminate, this is an indication that there is trouble with the connection
and communication will not proceed without solving the problem. If a copper connection is used
between the M65x and the hub/switch, check the following items:
1.
Verify that the connectors are fully engaged on each end.
2.
Verify that the cable used is a "straight-through" cable connected to a "normal" port.
Alternatively, a "cross-over" cable could be connected to an "uplink" port (this could later cause
confusion and is not recommended).
3.
Verify that both the M65x and hub/switch are powered.
4.
Try another cable.
5.
If a long CAT-5 cable is used, verify that is has never been kinked. Kinking can cause
internal discontinuities in the cable.
If a copper connection is used to an external fibre converter:
1.
Verify that the LINK LED on the converter is lit on at least one side. Both sides need to
be lit for a valid connection to be established.
2.
At least one brand of converters will not output an optical idle unless it receives a forced
10 Mb copper link pulse (for some reason, auto-negotiation pulses confuse it). Some
hubs/switches will not output an optical idle unless they receive an optical idle. This then inhibits
the converter from outputting a copper link pulse enabling the M65x to link. In this condition, no
device completes the link.
3.
Verify that the fibre converter(s) and/or fibre hub/switch are matched for the same type of
fibre connections. A 100BASE-FX port will NEVER inter-operate with the 10BASE-FL port (fibre
auto-negotiation does not exist).
4.
On the fibre connection, try swapping the transmit and receive connector on one end.
5.
Verify that the fibre converter(s) and/or fibre hub/switch use the proper optical wavelength
(100BASE-FX should be 1300nm).
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PXXX
Product Description
Alstom Grid
© - ALSTOM 2014. ALSTOM, the ALSTOM
logo and any alternative version thereof are
trademarks and service marks of ALSTOM.
The other names mentioned, registered or
not, are the property of their respective
companies. The technical and other data
contained in this document is provided for
information only. Neither ALSTOM, its officers
or employees accept responsibility for, or
should be taken as making any representation
or warranty (whether express or implied), as
to the accuracy or completeness of such data
or the achievement of any projected
performance criteria where these are
indicated. ALSTOM reserves the right to
revise or change this data at any time without
further notice.
Alstom Grid Worldwide Contact Centre
www.grid.alstom.com/contactcentre/
Tel: +44 (0) 1785 250 070
www.alstom.com
GRID